CN102198004A - Noninvasive near-infrared electronic blood-glucose meter - Google Patents
Noninvasive near-infrared electronic blood-glucose meter Download PDFInfo
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- CN102198004A CN102198004A CN2010101315814A CN201010131581A CN102198004A CN 102198004 A CN102198004 A CN 102198004A CN 2010101315814 A CN2010101315814 A CN 2010101315814A CN 201010131581 A CN201010131581 A CN 201010131581A CN 102198004 A CN102198004 A CN 102198004A
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Abstract
The invention relates to a noninvasive near-infrared electronic blood-glucose meter which can overcome defects such as wound presence and easy infection of electronic blood-glucose meters. The noninvasive near-infrared electronic blood-glucose meter takes a near-infrared spectroscopy technology and a DSP (Digital Signal Processing) technology as backgrounds. The structure is simple and reasonable, noninvasive blood-glucose measurement can be realized, and the noninvasive near-infrared electronic blood-glucose meter has the advantages of no infection, high measurement accuracy, short testing time, portability and no side effects. Meanwhile, the noninvasive near-infrared electronic blood-glucose meter has the memory function of the electronic blood-glucose meters, which can help diabetic patients to effectively arrange blood-glucose self-detection. In the invention, an optical instrument, namely, a halogen bulb, is used as an infrared source to irradiate the fingertip of one person, an infrared sensing array is used for receiving optical signals and performing photo-electric signal conversion, data calculation is completed through an A/D converter and the DSP technology, data storage and output are executed, finally the purpose of accurately detecting the blood-glucose of a human body is achieved.
Description
1. technical field
Patent of the present invention is a kind of non-invasive blood sugar test instrument.
2. background technology
The background technology of patent of the present invention is near-infrared spectrum technique and DSP technology.
3. summary of the invention
The problem that patent of the present invention will solve is that overcoming has wound, susceptible deficiency when the electronics blood glucose meter is used.
The beneficial effect of patent of the present invention is, provide a kind of simple and reasonable, can accomplish non-invasive blood glucose measurement, have do not take place to infect, the accuracy of measurement height, can portablely use, advantage such as the testing time lacks, have no side effect, the non-invasive near-infrared electronics blood glucose meter that has electronics blood glucose meter memory function simultaneously, the blood glucose oneself detects to help diabetics to carry out effectively.
Patent of the present invention is an infrared light supply irradiation human body finger tip with optical instrument halogen tungsten bulb (wavelength 600-2500nm), adopt infrared sensing array received optical signal and carry out the photosignal conversion, finish data computation by A/D converter and DSP technology, the line data of going forward side by side is stored and output, finally reaches the purpose of accurate human body blood glucose.
The concrete technical scheme of patent of the present invention is: at first infrared sensing array and A/D converter become analog voltage signal output with the blood sugar concentration information translation of human body hands point, and these signals are connected on the dsp processor by winding displacement.Because the output voltage range difference of each pick off, for the precision that makes the A/D conversion improves, sensor output signal will pass through signal conditioning circuit before this, and adopts the analogue filter circuit filtering interfering.After these pretreatment, dsp processor just can carry out computing accurately, and the result is deposited in the memorizer, finishes data accumulating.When needed, data are outputed on the LED display.
The theory support of patent of the present invention mainly contain following some:
3.1 near infrared spectrum ultimate principle
Near infrared light (NIR) is a kind of of infrared light, is the electromagnetic wave between visible light and mid-infrared light wave band, and ASTM (U.S.'s test and material tests association) is defined as it the electromagnetic wave of wavelength in 780~2526nm scope.Near infrared spectrum belongs to the absorption spectrum of molecular vibration spectrum, mainly produces during to the high level transition from ground state at molecular vibration, and body is had stronger penetration capacity.Near infrared light mainly is that because different Organic substances contains different groups, different groups has different energy levels, so different Organic substance absorbing wavelength near infrared light in different physicochemical environments has significant difference to the absorption of hydrogeneous radicals X-H vibration.During near infrared light, covibration will take place in light that frequency is identical and group, and the energy of light passes to molecule by the variation of molecular dipole moment; And the frequency of vibration of near-infrared light frequency and sample is when inequality, and the infrared light of this frequency just can not be absorbed.Therefore, when selecting the near infrared light sample that continuously changes frequency for use, because sample absorbs the selectivity of different frequency near infrared light, can die down in some wave-length coverage by the near infrared light behind the sample, the infrared light that transmits just carries the information of organic constituents and structure.The near infrared spectrum absorptance is little, thus by the infrared sensing array optical density signal of transmission is converted to the signal of telecommunication, and after using DSP to carry out date processing, just can accurately determine the content of sample component.
3.2 the operation principle of near infrared spectrum monitoring blood sugar concentration
Use the resulting near infrared spectrum of near infrared light human body skin, certainty and the nature parameters that sees through structure as blood sugar concentration, have intrinsic contact.Use chemometrics method that both are carried out association, can establish qualitative and quantitative relationship between the two, i.e. detection model.After setting up model,, the data base is retrieved, just can predict the nature parameters of sample as long as measure the near infrared spectrum of unknown sample.So whole near-infrared spectral analytical method has comprised correction and predicted two processes, promptly at first sets up detection model, predict the composition and the character of sample then by detection model.(as Fig. 1)
3.3 infrared emission and sensor array
3.3.1 the interference factor in the blood glucose measurement
Blood glucose content in blood is lower, and is also fainter to the absorption of near infrared light.Materials such as other compositions such as hematochrome, cholesterol, albumin are than the glucose content height in the blood, and are also more intense to the Absorption of light.(as table 1)
| Blood constituent | Term of reference |
| Water | 78-78.8g/dl |
| Hematochrome | 6-18g/dl |
| Glucose | 40-500mg/dl |
| Cholesterol | 80-800mg/dl |
| Albumin | 3-5g/dl |
The different blood constituent content of table 1. term of reference
A large amount of experiment confirms, water, hematochrome, albumin, blood constituents such as cholesterol have overlapping interference in the near infrared spectrum district, need be with the minimum interference of these materials to flashlight when detecting glucose information.
In addition, scattering and absorption also easily take place near infrared light in by tissue.As at finger tip, near infrared light sees through tissue can a weakened 3-4 absorbance units, and the variation of the concentration of glucose of 0.2mmoL/L, the about 0.4-0.6 of the variation of a spectral absorption absorbance units.As seen, in the tissue the pairing spectral information of the slight change of concentration of glucose change very faint, the extremely difficult requirement that reaches accurate Calculation of single-sensor.Therefore, the energy that has only a plurality of specific wavelengths to glucose absorption peak district to absorb detects, select the spectrum of a part to the blood sugar concentration sensitivity, the spectrum that a part is lower to the change of blood sugar sensitivity, could reduce the influence of other composition in the blood to greatest extent, obtain concentration of glucose change information more accurately.
For this reason, the infrared sensing array that " non-invasive infrared exoelectron blood glucose meter " uses a plurality of pick offs to form is surveyed the glucose absorption spectrum of different wavelength range simultaneously, message complementary sense, then after testing model draw than single-sensor accurate the blood glucose value of Duoing.In the array wave-length coverage of each sensor measurement in total wavelength band according to the sensitivity segment assignments of glucose, can farthest remove overlay information and interference like this, the optical information that concentration of glucose is changed is converted into electrical signal accurately and efficiently, for further date processing provides accurate information.
3.3.2 the selection of blood glucose measurement medium wavelength
The absworption peak of water is about 1450nm and 1900nm, and the absorption of skin pigment layer mainly concentrates on below the 1200nm.And glucose exists absorption widely at 600-2500nm, especially in the 2000-2500nm scope, 2105nm is arranged, a plurality of absworption peaks such as 2168nm, 2273nm and 2326nm; In the 1450-1850nm scope, also exist a plurality of absworption peaks such as 1410nm, 1540nm, 1590nm and 1732nm.Protein, plasma protein change less on these wavelength, so use the 1050-2450nm wave band concentration of glucose are detected, and can obtain good effect.
Therefore, " non-invasive near-infrared electronics blood glucose meter " uses the optical instrument halogen tungsten bulb, and wave-length coverage is 600-2500nm.In this scope, select responsive and insensitive a plurality of wave band, can react the light absorption situation of blood glucose more all sidedly blood glucose, thus measuring blood information effectively.In addition, because there is not harmful radiation near infrared light, and the intensity of light source can not cause damage to human body, so " non-invasive near-infrared electronics blood glucose meter " can not produce any side effect to the experimenter.
3.4 the foundation of detection model
From the data that sensor array collects, it is overlapping to have certain spectral information, therefore will be eliminated by the processing of detection model.For this reason, should set up linear model and nonlinear model, finally receive the good result of accurate mensuration blood glucose value to improve detection model.
3.4.1 the foundation of linear model
Result according to external whole blood experiment detection concentration of glucose absorption spectrum gained can learn that glucose and the water absorbance at its characteristic absorption peak place had tangible linear change when concentration of glucose changed in physiology, pathology scope.(as table 2)
| Absworption peak sample | 100mg/dl | 200mg/dl | 300mg/dl | 400mg/dl | 500mg/dl |
| Glucose absorption peak 1732nm | 0.4950 | 0.4995 | 0.5009 | 0.5019 | 0.5032 |
| Glucose absorption peak 2168nm | 0.8612 | 0.8639 | 0.8674 | 0.8707 | 0.8750 |
| Water absworption peak 1452nm | 1.2540 | 1.2483 | 1.2445 | 1.2398 | 1.2348 |
| Water absworption peak 1948nm | 3.9964 | 3.8911 | 3.8064 | 3.7185 | 3.6194 |
The absorbance meansigma methods at the different blood sugar concentrations of table 2., different absworption peaks place
As seen, glucose absorption peak 1732nm and 2168nm place absorbance increase along with the increase of concentration, and water absworption peak 1452nm and 1948nm place absorbance reduce along with the increase of concentration.In addition, the amplitude of variation at water absworption peak place is greater than the variation at place, glucose absorption peak.Therefore, when the signal of design infrared sensing array received, the variation of water absworption peak place optical information is considered wherein, can be assisted the mensuration of concentration of glucose well.
3.4.2 the correction of linear model
Parameters such as the skin at the intravital fat of people, albumen, moisture and detection position, fingernail, tissue all have fixed influence to blood sugar test.What wherein have the greatest impact is reflective, moisture and the fat of skin, and the special absorption peak of protein available spectrum is avoided its interference.By collecting the health screening data result, set up the parameter that body fat, moisture, skin reflex influence spectral absorption.Wherein, people's body weight be height, age function W (H, A), fat and water and body weight have functional relationship F (W), the reflective of skin also with age, body weight have functional relationship R (A, W).Therefore the variation of emergent light can be modified to: Δ I=I-(I
Dc+ I
f+ I
r+ I
t+ I
g).Wherein: Δ I is the equation of light; I
DcBe scattered light; I
f, I
r, I
t, I
gBe respectively fat, skin reflex, glucose and other light absorption, by W (H, A), (A W) calculates separately Relation Parameters, and they are shown a with coefficient table respectively for F (W), R
1, a
2, a
3, a
4, a
5, then following formula can be: Δ I=I-I (a
1+ a
2+ a
3+ a
4+ a
5).According to Lambert-Beer's law D=LnI/I
0(wherein: I, I0 are respectively incident intensity and output intensity to=Ecd; C is a material concentration; D is the path that light passes material; E is the absorption coefficient of light of certain material; D is an optical density), the glucose variable quantity of this formula detection model is represented with Δ PG the absorptance am (λ) of same absorbent part replaces S=dam (λ), T=(a1+a2+a3+a4+a5) with aG (λ).The sensitivity that definition detects is the ratio of variation with the infrared light intensity I variation of concentration of glucose Δ PG, and expression formula is:
Concentration of glucose can be expressed as:
From equation as can be seen, blood sugar concentration C
G(λ) with absorptance a
M(λ), a
GCorresponding relation (λ) can tentatively be proofreaied and correct linear model for the basis by this formula.
3.4.3 the foundation of nonlinear model
In fact, because serious interference between each component often is nonlinear response between spectrum and the blood sugar concentration, this just requires and must set up nonlinear model on the basis of above linear model, further improves the accuracy of data.For this reason, setting up in the process of " non-invasive near-infrared electronics blood glucose meter " detection model, used non-linear correction method---based on the mixing expert algorithm of neutral net.Its basic ideas are for each pick off in the infrared sensing array (experiencing certain wavelength) is provided with weight, to calculate the weighted mean of blood sugar detection value.Fig. 2 is a non-linear mould predictive result (wave band: 2000-2400nm)
In sum, by combining of sensor array and nonlinear model, " non-invasive near-infrared electronics blood glucose meter " can measure experimenter's blood glucose concentration value very accurately.
3.5DSP processor (containing the 12bit A/D converter)
" noinvasive near-infrared electronics blood glucose meter " is data processing core with the dsp processor, and allomeric function is imported by data, DSP control and date processing, and LED display output three cooperation is finished.
3.6 detect the selection at position
The selection reference of measuring point should be from following some consideration:
1. blood is abundant;
2. should select the human body exsertion part as far as possible, make the experimenter all be easy to accept, and be convenient for measuring from psychology and physiological angle;
3. realize the position of optical measurement sampling easily, reduce gauge and realize difficulty;
4. consider between experimenter's sex, age and the health there are differences, should select the less position of individual variation, reduce the influence of extraneous factor as far as possible measurement result;
5. the inside of human body factor is disturbed less position, as the influence of body temperature, pulse etc.
Specifically, the uncertain factor of human body is more in infrared Woundless blood sugar is measured, and expect best testing result, the detection position that must select a suitable near infrared ray to penetrate.The external fat of branch of dewatering is a significant effects factor.Therefore, be sensitivity and the reliability of minimise interference factor, detect and preferably select position lean, that penetrance good, convenience is tested to carry out to adapt to glucose detection.Tongue fatty minimum, penetrance is good, but is inconvenient to detect.Detect more conveniently at the ear-lobe place, but fat content is more relatively, so can influence the accuracy of measurement to a certain extent.Because the finger tip fat ratio is less, infrared light penetrates easily, and the internal and external factor influence is less; And convenient test, the experimenter is easy to accept psychologically, is the measuring point so should select finger tip.
4. description of drawings
Fig. 1 is a near-infrared spectrum analysis blood glucose research method sketch map.
Fig. 2 is a non-linear mould predictive result (wave band: 2000-2400nm)
Fig. 3 is " non-invasive near-infrared electronics blood glucose meter " fundamental diagram.
Fig. 4 is " non-invasive near-infrared electronics blood glucose meter " product appearance figure.
5. the specific embodiment
Below in conjunction with accompanying drawing patent of the present invention is further described.
Embodiment sees Fig. 1.During use, open shift knob 7.After treating that main frame 4 enters duty, test clip 1 is sandwiched in finger fingertip, function of use selector button 5 is selected the blood sugar test function, and presses ACK button 6 beginning blood sugar test.After hanging on, LED display 3 shows the detection data.At this moment, but function of use selector button 7 is selected hold function, and presses ACK button 6 and carry out the data preservation.In addition, can also select query function, and press the inquiry that ACK button 6 is stored data.User can be closed main frame 4 after pressing shift knob 5 once more.
Claims (8)
1. non-invasive near-infrared electronics blood glucose meter, with near-infrared spectrum technique and DSP technology is technical background, it is characterized in that: with the optical instrument halogen tungsten bulb is infrared light supply irradiation human body finger tip, adopt infrared sensing array received optical signal and carry out the photosignal conversion, the infrared sensing array connects A/D converter by circuit and dsp processor is finished data computation, and with data storage with memorizer that dsp processor links to each other in, output to when needed with LED display that dsp processor links to each other on.
2. non-invasive near-infrared electronics blood glucose meter according to claim 1 is characterized in that: described infrared light supply wavelength covers 600-2500nm, thereby covers the absworption peak of glucose and water in this wave band.
3. non-invasive near-infrared electronics blood glucose meter according to claim 1 is characterized in that: described infrared sensing array, and according to mixing expert algorithm, for each pick off of experiencing different wave length is provided with weight based on neutral net.
4. non-invasive near-infrared electronics blood glucose meter according to claim 1, it is characterized in that: described infrared sensing array, receive the optical signalling of following wavelength, glucose absorption peak: 1410nm, 1540nm, 1590nm, 1732nm, 2105nm, 2168nm, 2273nm and 2326nm; Water absworption peak: 1452nm and 1948nm.
5. non-invasive near-infrared electronics blood glucose meter according to claim 1 is characterized in that: described dsp processor, use the detection model of setting up with based on the mixing expert algorithm of neutral net, as the basis of its date processing.
6. non-invasive near-infrared electronics blood glucose meter according to claim 1, it is characterized in that: described dsp processor, receive the unlike signal of each pick off conversion in the infrared sensing array,, obtain the final measured value of blood sugar concentration by calculating the weighted mean of all data.
7. non-invasive near-infrared electronics blood glucose meter according to claim 1, it is characterized in that: optical instrument halogen tungsten bulb and infrared sensing array are positioned at test clip (1), and test clip (1) links to each other with main frame (4) by data call wire (2).
8. main frame according to claim 7 (4) is characterized in that: include dsp processor (containing A/D converter) and other circuit, LED display (3), function selecting button (5), ACK button (6) and shift knob (7) are arranged on the main frame.
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| CN102512179A (en) * | 2011-12-27 | 2012-06-27 | 王培勇 | Non-destructive detector for human blood sugar |
| CN103690176A (en) * | 2013-12-26 | 2014-04-02 | 苏州大学 | Method for testing blood glucose in non-invasive manner |
| CN104382605A (en) * | 2014-12-19 | 2015-03-04 | 新乡医学院 | Method for noninvasive and quick determination of blood glucose of rat |
| CN104382602A (en) * | 2014-11-27 | 2015-03-04 | 龙泉千成电子科技有限公司 | Multi-parameter intelligent physiological detection glove |
| CN104473651A (en) * | 2014-12-17 | 2015-04-01 | 杜清静 | Infrared spectrum technology non-invasive blood glucose instrument |
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| CN103690176A (en) * | 2013-12-26 | 2014-04-02 | 苏州大学 | Method for testing blood glucose in non-invasive manner |
| CN103690176B (en) * | 2013-12-26 | 2015-10-28 | 苏州大学 | A kind of Noninvasive Blood Glucose Detection Methods |
| CN104382602A (en) * | 2014-11-27 | 2015-03-04 | 龙泉千成电子科技有限公司 | Multi-parameter intelligent physiological detection glove |
| CN104473651A (en) * | 2014-12-17 | 2015-04-01 | 杜清静 | Infrared spectrum technology non-invasive blood glucose instrument |
| CN104382605A (en) * | 2014-12-19 | 2015-03-04 | 新乡医学院 | Method for noninvasive and quick determination of blood glucose of rat |
| CN104970802A (en) * | 2015-06-30 | 2015-10-14 | 成都冠禹科技有限公司 | Intelligent glucometer |
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| CN108784712A (en) * | 2018-06-20 | 2018-11-13 | 四川大学 | A kind of optical detecting method of the dynamic Woundless blood sugar concentration based near infrared band |
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Application publication date: 20110928 |